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Reactive Separation for Process Intensification and Sustainability [electronic resource].

By: Cardona Alzate, Carlos ArielContributor(s): Sanchez, Mariana Ortiz | Andrianovich, Pisarenko YuriMaterial type: TextTextPublisher: Milton : CRC Press LLC, 2019Description: 1 online resource (225 p.)ISBN: 9781000751017; 1000751015; 9780429300387; 0429300387; 9781000751253; 1000751252Subject(s): Separation (Technology) | SCIENCE / Chemistry / Industrial & Technical | TECHNOLOGY / Engineering / Chemical & BiochemicalDDC classification: 660.3 LOC classification: TP156.S45Online resources: Taylor & Francis | OCLC metadata license agreement
Contents:
Cover -- Half Title -- Title Page -- Copyright Page -- Dedication -- Table of Contents -- List of Figures -- List of Tables -- Preface -- Acknowledgments -- Authors -- List of Abbreviations -- 1: Reactive Separation Processes as a Key Strategy for Sustainable Use of Natural Resources: Definition, Advantages and Disadvantages, Phenomenology -- 1.1 Reactive Separation Processes as Alternative for Improving the Processes Sustainability -- 1.2 Reactive Separation Processes: An Example of Intensification -- 1.3 Reactive Separation Processes: Definition -- 1.4 Phenomenology
1.5 Advantages and Disadvantages -- References -- 2: Basic Aspects of Reactive Separation Processes: Classification, Range of Applications, Reactive Separation Processes in the Industry, Design Methods and Strategies, Successful Cases Improving Process Sustainability -- 2.1 Classification of Reactive Separation Processes -- 2.2 Range of Applications -- 2.3 Design Methods and Strategies -- 2.3.1 Process Synthesis -- 2.3.2 Modeling and Simulation -- 2.4 Successful Cases Improving Process Sustainability -- 2.4.1 Ethanol Production -- 2.4.2 Biodiesel Through Reactive Absorption
2.4.3 Ethyl Acetate: Comparison of Technologies -- References -- 3: Reactive Distillation: Uses and Applications, Analysis of the Statics, Modeling and Simulation, Case Study -- 3.1 Introduction -- 3.2 Model -- 3.3 Strategy and Basic Concepts of the Analysis of the Statics -- 3.4 Trajectory Construction -- 3.5 The Basic Algorithm of the Analysis of the Statics -- 3.6 Case Study: Mesityl Oxide -- 3.7 Other Approaches to Analyze and Design Reactive Distillation Processes -- 3.7.1 RD in Dividing Wall Columns -- 3.7.2 Enzymatic RD -- 3.8 Conclusions -- References
4: Reactive Extraction and Extractive Fermentation: Uses and Applications, Conceptual Design, Modeling and Simulation, Case Study -- 4.1 Classification of Reactive Extraction Processes by Chemical Type -- 4.1.1 Reactive Extraction -- 4.1.2 Extractive Reaction -- 4.1.3 Extractive Fermentation -- 4.2 Modeling of a Reactor-Extractor -- 4.2.1 Equilibrium Model for Reactive Extraction Processes -- 4.3 Modeling of Extractive Fermentation -- 4.4 Case Study -- 4.4.1 Analysis of a Reactive Extraction Process for Biodiesel Production Using a Lipase Immobilized on Magnetic Nanostructure
4.4.2 Liquid-Liquid Equilibrium Equation -- 4.4.3 Simulation Procedure -- 4.4.4 Reactive Extraction Process -- 4.4.5 Continuous Process -- 4.4.6 Multistage Reactor Extractor -- 4.4.7 Location of the Biocatalyst Using Magnetic Fields -- 4.4.8 Conclusions -- References -- 5: Reactive Absorption: Uses and Applications, Conceptual Design, Modeling and Simulation, Case Study -- 5.1 Definition -- 5.2 Classification -- 5.3 Advantages and Disadvantages -- 5.4 Uses and Applications -- 5.5 Conceptual Design -- 5.6 Modeling and Simulation -- 5.7 Case Study -- 5.7.1 Considerations and Assumptions
Summary: This book describes, analyses and discusses the main principles, phenomena and design strategies of reactive separation processes with an emphasis on the intensification as a basis of the sustainability. Different reactive separation processes are explained in detail to show the phenomena and with the purpose of understanding when their use allows advantages based on the output results. Case examples are analysed and the perspective of these processes in the future is discussed. The overall sustainability of reactive separation processes in the industry is also explained separately.
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Cover -- Half Title -- Title Page -- Copyright Page -- Dedication -- Table of Contents -- List of Figures -- List of Tables -- Preface -- Acknowledgments -- Authors -- List of Abbreviations -- 1: Reactive Separation Processes as a Key Strategy for Sustainable Use of Natural Resources: Definition, Advantages and Disadvantages, Phenomenology -- 1.1 Reactive Separation Processes as Alternative for Improving the Processes Sustainability -- 1.2 Reactive Separation Processes: An Example of Intensification -- 1.3 Reactive Separation Processes: Definition -- 1.4 Phenomenology

1.5 Advantages and Disadvantages -- References -- 2: Basic Aspects of Reactive Separation Processes: Classification, Range of Applications, Reactive Separation Processes in the Industry, Design Methods and Strategies, Successful Cases Improving Process Sustainability -- 2.1 Classification of Reactive Separation Processes -- 2.2 Range of Applications -- 2.3 Design Methods and Strategies -- 2.3.1 Process Synthesis -- 2.3.2 Modeling and Simulation -- 2.4 Successful Cases Improving Process Sustainability -- 2.4.1 Ethanol Production -- 2.4.2 Biodiesel Through Reactive Absorption

2.4.3 Ethyl Acetate: Comparison of Technologies -- References -- 3: Reactive Distillation: Uses and Applications, Analysis of the Statics, Modeling and Simulation, Case Study -- 3.1 Introduction -- 3.2 Model -- 3.3 Strategy and Basic Concepts of the Analysis of the Statics -- 3.4 Trajectory Construction -- 3.5 The Basic Algorithm of the Analysis of the Statics -- 3.6 Case Study: Mesityl Oxide -- 3.7 Other Approaches to Analyze and Design Reactive Distillation Processes -- 3.7.1 RD in Dividing Wall Columns -- 3.7.2 Enzymatic RD -- 3.8 Conclusions -- References

4: Reactive Extraction and Extractive Fermentation: Uses and Applications, Conceptual Design, Modeling and Simulation, Case Study -- 4.1 Classification of Reactive Extraction Processes by Chemical Type -- 4.1.1 Reactive Extraction -- 4.1.2 Extractive Reaction -- 4.1.3 Extractive Fermentation -- 4.2 Modeling of a Reactor-Extractor -- 4.2.1 Equilibrium Model for Reactive Extraction Processes -- 4.3 Modeling of Extractive Fermentation -- 4.4 Case Study -- 4.4.1 Analysis of a Reactive Extraction Process for Biodiesel Production Using a Lipase Immobilized on Magnetic Nanostructure

4.4.2 Liquid-Liquid Equilibrium Equation -- 4.4.3 Simulation Procedure -- 4.4.4 Reactive Extraction Process -- 4.4.5 Continuous Process -- 4.4.6 Multistage Reactor Extractor -- 4.4.7 Location of the Biocatalyst Using Magnetic Fields -- 4.4.8 Conclusions -- References -- 5: Reactive Absorption: Uses and Applications, Conceptual Design, Modeling and Simulation, Case Study -- 5.1 Definition -- 5.2 Classification -- 5.3 Advantages and Disadvantages -- 5.4 Uses and Applications -- 5.5 Conceptual Design -- 5.6 Modeling and Simulation -- 5.7 Case Study -- 5.7.1 Considerations and Assumptions

5.7.2 Input Data

This book describes, analyses and discusses the main principles, phenomena and design strategies of reactive separation processes with an emphasis on the intensification as a basis of the sustainability. Different reactive separation processes are explained in detail to show the phenomena and with the purpose of understanding when their use allows advantages based on the output results. Case examples are analysed and the perspective of these processes in the future is discussed. The overall sustainability of reactive separation processes in the industry is also explained separately.

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